Friday, February 16, 2024

 SPACE

Can astronomers use radar to spot a cataclysmic asteroid?


Scientists share their latest findings and the future of radar in planetary science and defense


Reports and Proceedings

GREEN BANK OBSERVATORY





How can humans protect the Earth from “devastating asteroid and comet impacts?” According to the National Academies and their 2023-2032 Planetary Science and Astrobiology Decadal Survey, ground based astronomical radar systems will have a “unique role” to play in planetary defense.

There is currently only one system in the world concentrating on these efforts, NASA’s Goldstone Solar System Radar, part of the Deep Space Network (DSN). However, a new instrument concept from the National Radio Astronomy Observatory (NRAO) called the next generation RADAR (ngRADAR) system will use the National Science Foundation’s Green Bank Telescope (GBT) and other current and future facilities to expand on these capabilities.

“There are many applications for the future of radar, from substantially advancing our knowledge of the Solar System, to informing future robotic and crewed spaceflight, and characterizing hazardous objects that stray too close to Earth,” shares Tony Beasley, NRAO’s director.

On Saturday, February 17th, scientists will showcase recent results obtained with ground-based radar systems at the American Association for the Advancement of Science’s annual conference in Denver, Colorado.

“NRAO, with the support of the National Science Foundation and oversight by Associated Universities, Inc., has a long history of using radar to further our understanding of the Universe. Most recently the GBT helped confirm the success of NASA’s DART mission, the first test to see if humans could successfully alter the trajectory of an asteroid, “ shares NRAO scientist and ngRADAR project director Patrick Taylor.

The GBT is the world’s largest fully steerable radio telescope. The maneuverability of its 100-meter dish enables it to observe 85 percent of the celestial sphere, allowing it to quickly track objects across its field of view. Adds Taylor, “With the support of Raytheon Technologies, ngRADAR pilot tests on the GBT—using a low-power transmitter with less output than a standard microwave oven—have produced the highest-resolution images of the Moon ever taken from Earth. Imagine what we could do with a more powerful transmitter.”

Scientists sharing their results at AAAS include Edgard G. Rivera-Valentín of Johns Hopkins Applied Physics Laboratory and Marina Brozović of NASA’s Jet Propulsion Laboratory, which manages Goldstone and the DSN.  Adds Brozović, “The public might be surprised to learn that the technology we use in our current radar at Goldstone hasn’t changed much since World War II. For 99% of our observations, we transmit and receive from this one antenna. New radar transmitter designs, like ngRADAR on the GBT, have the potential to significantly increase the output power and waveform bandwidth, allowing for even higher resolution imaging. It will also produce a scalable and more robust system by using telescope arrays to increase the collecting area.”

“NRAO is an ideal organization to lead these efforts because of the instruments we have available to receive radar signals, like the Very Long Baseline Array has done in our pilot ngRADAR project,” explains Brian Kent, NRAO scientist and director of science communications, who coordinated the presentation at AAAS, “Future facilities like the next generation Very Large Array, as a receiver, will create a powerful combination for planetary science.”

How does ground-based astronomical radar expand our understanding of the Universe? By allowing us to study our nearby Solar System, and everything in it, in unprecedented detail. Radar can reveal the surface and ancient geology of planets and their moons, letting us trace their evolution. It can also determine the location, size, and speed of potentially hazardous Near Earth Objects, like comets or asteroids. Advances in astronomical radar are opening new avenues, renewed investment, and interest in joint industry and scientific community collaborations as a multidisciplinary venture. 

About NRAO & GBO

The National Radio Astronomy Observatory (NRAO) is a facility of the National Science Foundation, operated under cooperative agreement by Associated Universities, Inc.

The Green Bank Observatory is a facility of the National Science Foundation and is operated by Associated Universities, Inc.

Laboratory study on conditions for spontaneous excitation of "chorus emission," wave of space plasma


Exploring common plasma phenomena in laboratory and space through experiments in the RT-1 artificial magnetosphere


Peer-Reviewed Publication

NATIONAL INSTITUTES OF NATURAL SCIENCES

Observation of Spontaneous Chorus Emission in RT-1: Frequency Variation in Plasma Confined by Dipole Magnetic Field with High-Temperature Electrons. 

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WHEN THE PLASMA CONFINED IN THE DIPOLE MAGNETIC FIELD OF RT-1 CONTAINS A SIGNIFICANT RATIO OF HIGH-TEMPERATURE ELECTRONS (RED PARTICLES), THE SPONTANEOUS FORMATION OF A CHORUS EMISSION (WHITE EMISSION LINES) IS CHARACTERIZED BY A VARIABLE FREQUENCY (SOUND HEIGHT) LIKE BIRDSONG.

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CREDIT: NATIONAL INSTITUTE FOR FUSION SCIENCE



A dipole magnetic field, created by a ring current, is the most fundamental type of magnetic field that is found both in laboratories and in space. Planetary magnetospheres, such as Jupiter's, effectively confine plasma. The RT-1 project aims to learn from nature and create a magnetosphere-type high-performance plasma to realize advanced fusion energy. Simultaneously, the artificial magnetosphere offers a means to experimentally understand the mechanisms of natural phenomena in a simplified and controlled environment.
The whistler mode chorus emission, observed in the space surrounding the Earth, known as "Geospace", is an important phenomenon which is related to the aurorae and space weather. The chorus emission has been actively investigated primarily through spacecraft observations, theoretical studies, and numerical simulations. While spacecraft are powerful tools for studying the actual space environment, the planetary magnetosphere is a huge and complex system that is difficult to understand in its entirety. Also, it is not easy for human beings to manipulate the space environment. On the contrary, laboratory settings allow us to create a simplified research object that is extracted from the complex properties of nature in a controlled environment. Therefore, experimental studies are expected to play a complementary role in the observation and theory of understanding chorus emissions. However, it is not straightforward to create a magnetospheric environment in the laboratory. Laboratory experiments on chorus emissions in a magnetospheric dipole magnetic field have never so far been conducted.

A research team from the National Institute for Fusion Science in Toki, Japan, and the Graduate School of Frontier Sciences at the University of Tokyo in Kashiwa, Japan, has successfully conducted laboratory studies on the whistler mode chorus emission using the RT-1 device. This "artificial magnetosphere" has a magnetically levitated superconducting coil to create a planetary magnetosphere-type dipole magnetic field in the laboratory. Using high-temperature superconducting technology, a 110 kg coil is magnetically levitated in a vacuum vessel, and the generated magnetic field confines the plasma. This unique setup allows operation without any mechanical support structures to the coil, making it possible to generate plasma in an environment akin to that of a planetary magnetosphere, even within a ground-based facility. In this study, the research team filled the vacuum vessel of the RT-1 with hydrogen gas and injected microwaves to create high-performance hydrogen plasma, primarily by heating electrons.
 

In the experiments plasmas were generated in various states and investigations into the generation of waves were made. Consequently, a spontaneous production of the whistler wave chorus emission was observed when the plasma contained a considerable ratio of high-temperature electrons. Measurements were also taken of the strength and frequency of the chorus emission from the plasma, focusing on its density and the state of the high-temperature electrons. The findings revealed that the generation of a chorus emission is driven by an increase in high-temperature electrons, responsible for plasma pressure. Additionally, increasing the overall plasma density had the effect of suppressing the generation of the chorus emission. Through this study, it was clarified that the chorus emission is a universal phenomenon occurring in plasma with high-temperature electrons in a simple dipole magnetic field. Properties revealed in the experiment, including appearance conditions and wave propagation, may enhance our understanding of the chorus emission and related phenomena observed in geospace.

These results have been published in a journal of the Nature publishing group, Nature Communications.

Electromagnetic waves of a chorus emission have the potential to further accelerate hot electrons to higher energy states, leading to the formation of aurorae and satellite failures. These electromagnetic waves, along with energetic particles, play a crucial role in space weather phenomena. In geospace, when explosive events (flares) occur on the solar surface, they give rise to magnetic storms, causing large fluctuations in the electromagnetic field and the generating large amounts of energetic particles. This not only causes satellite failures and impacts the ozone layer but is also known to disrupt power and communication networks on the ground. With the expansion of human activity today, understanding space weather phenomena has become increasingly important. However, numerous mechanisms and phenomena in this area remain unresolved. The outcome of this study is expected to contribute to a better understanding of the mechanisms behind the diverse space weather phenomena.

 

In the field of fusion plasma, which aims to ultimately solve energy problems, the loss of particles and structure formation due to interaction with waves is one of the central research issues. A precise understanding of the complex interactions between spontaneously excited waves and plasma is essential for achieving fusion. Wave phenomena with frequency variations have been widely observed in high-temperature plasmas for fusion, indicating the existence of a shared physical mechanism with the chorus emission. The findings from this study represent a step forward in comprehending the common physical phenomena found in both fusion and space plasmas. It is anticipated that future research will advance further with increased cooperation between these two fields.

 

Glossary

Whistler mode chorus emission

Whistler waves are one of the fundamental waves propagating in plasma. In chorus emissions observed around geospace and Jupiter, fluctuation events with frequency variations similar to birdsong occur repeatedly. They are thought to be closely related to aurorae and space weather phenomena, such as the production and transport of high-energy electrons.

 

Ring Trap 1 device (RT-1)

The RT-1 is an experimental apparatus located at the University of Tokyo. Utilizing high-temperature superconducting technology, a dipole field coil is magnetically levitated, enabling plasma experiments to be conducted in an environment close to that of the planetary magnetosphere.

 

Dipole magnetic field

The dipole field is the configuration of a magnetic field produced by a ring current. The shape of planetary magnetospheres, such as Earth and Jupiter, closely resembles a dipole magnetic field which is characterized by a highly non-uniform strength, rapidly weakening as it expands away. This unique characteristic enables the stable confinement of high-performance plasma.

 

Geospace

Geospace is the space around the Earth that is particularly closely linked to human activities. In this region, plasma confined by the Earth's magnetic field gives rise to various phenomena. With the expansion of human activities into space, the study of magnetospheric disturbances, capable of causing aurora phenomena, as well as power and communication failures, has emerged as an active research field known as "space weather”.

Exploring Chorus Emission of Space Plasma in Laboratory: Experiments in Artificial Magnetosphere RT-1 to Understand Nature and Advance Fusion Research 

 

SwRI scientists find evidence of geothermal activity within icy dwarf planets


Webb telescope observes potentially young methane deposits on surfaces of Eris, Makemake

Peer-Reviewed Publication

SOUTHWEST RESEARCH INSTITUTE

Eris-Makemake-possible-processes 

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SWRI SCIENTISTS USED DATA FROM THE JAMES WEBB SPACE TELESCOPE TO MODEL THE SUBSURFACE GEOTHERMAL PROCESSES THAT COULD EXPLAIN HOW METHANE ENDED UP ON THE SURFACES OF ERIS AND MAKEMAKE, TWO DWARF PLANETS IN THE DISTANT KUIPER BELT. THE ILLUSTRATION POINTS TO THREE POSSIBILITIES, INCLUDING THE POTENTIAL THAT LIQUID WATER EXISTS WITHIN THESE ICY BODIES AT THE EDGE OF THE SOLAR SYSTEM, FAR FROM THE HEAT OF THE SUN.

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CREDIT: SOUTHWEST RESEARCH INSTITUTE




SAN ANTONIO — February 15, 2024 —A team co-led by Southwest Research Institute found evidence for hydrothermal or metamorphic activity within the icy dwarf planets Eris and Makemake, located in the Kuiper Belt. Methane detected on their surfaces has the tell-tale signs of warm or even hot geochemistry in their rocky cores, which is markedly different than the signature of methane from a comet.

“We see some interesting signs of hot times in cool places,” said SwRI’s Dr. Christopher Glein, an expert in planetary geochemistry and lead author of a paper about this discovery. “I came into this project thinking that large Kuiper Belt objects (KBOs) should have ancient surfaces populated by materials inherited from the primordial solar nebula, as their cold surfaces can preserve volatiles like methane. Instead, the James Webb Space Telescope (JWST) gave us a surprise! We found evidence pointing to thermal processes producing methane from within Eris and Makemake.

The Kuiper Belt is a vast donut-shaped region of icy bodies beyond the orbit of Neptune at the edge of the solar system. Eris and Makemake are comparable in size to Pluto and its moon Charon. These bodies likely formed early in the history of our solar system, about 4.5 billion years ago. Far from the heat of our Sun, KBOs were believed to be cold, dead objects. Newly published work from JWST studies made the first observations of isotopic molecules on the surfaces of Eris and Makemake. These so-called isotopologues are molecules that contain atoms having a different number of neutrons. They provide data that are useful in understanding planetary evolution.

The JWST team measured the composition of the dwarf planets’ surfaces, particularly the deuterium (heavy hydrogen, D) to hydrogen (H) ratio in methane. Deuterium is believed to have formed in the Big Bang, and hydrogen is the most abundant nucleus in the universe. The D/H ratio on a planetary body yields information about the origin, geologic history and formation pathways of compounds containing hydrogen.

“The moderate D/H ratio we observed with JWST belies the presence of primordial methane on an ancient surface. Primordial methane would have a much higher D/H ratio,” Glein said. “Instead, the D/H ratio points to geochemical origins for methane produced in the deep interior. The D/H ratio is like a window. We can use it in a sense to peer into the subsurface. Our data suggest elevated temperatures in the rocky cores of these worlds so that methane can be cooked up. Molecular nitrogen (N2) could be produced as well, and we see it on Eris. Hot cores could also point to potential sources of liquid water beneath their icy surfaces.”

Over the past two decades, scientists have learned that icy worlds can be much more internally evolved than once believed. Evidence for subsurface oceans has been found at several icy moons such as Saturn’s moon Enceladus and Jupiter’s moon Europa. Liquid water is one of the key ingredients in determining potential planetary habitability. The possibility of water oceans inside Eris and Makemake is something that scientists are going to study in the years ahead. If either of them is habitable, then it would become the most distant world in the solar system that could possibly support life. Finding chemical indicators of internally driven processes takes them a step in this direction.

“If Eris and Makemake hosted, or perhaps could still host warm, or even hot, geochemistry in their rocky cores, cryovolcanic processes could then deliver methane to the surfaces of these planets, perhaps in geologically recent times,” said Dr. Will Grundy, an astronomer at Lowell Observatory, one of Glein's co-authors and lead author of a companion paper. “We found a carbon isotope ratio (13C/12C) that suggests relatively recent resurfacing.”

This work is part of a paradigm shift in planetary science. It is increasingly being recognized that cold, icy worlds may be warm at heart. Models developed for this study additionally point to the formation of geothermal gases on Saturn’s moon Titan, which also has abundant methane. Furthermore, the inference of unexpected activity on Eris and Makemake underscores the importance of internal processes in shaping what we see on large KBOs and is consistent with findings at Pluto.

“After the New Horizons flyby of the Pluto system, and with this discovery, the Kuiper Belt is turning out to be much more alive in terms of hosting dynamic worlds than we would have imagined,” said Glein. “It’s not too early to start thinking about sending a spacecraft to fly by another one of these bodies to place the JWST data into a geologic context. I believe that we will be stunned by the wonders that await!”

Access Glein’s Icarus paper, “Moderate D/H ratios in methane ice on Eris and Makemake as evidence of hydrothermal or metamorphic processes in their interiors: Geochemical analysis,” at: https://doi.org/10.1016/j.icarus.2024.115999 or https://arxiv.org/abs/2309.05549.

For more information, visit https://www.swri.org/planetary-science.

A team co-led by Southwest Research Institute found evidence for hydrothermal or metamorphic activity deep within the icy dwarf planets Eris and Makemake (artistic illustration). Located in the Kuiper Belt, a vast donut-shaped region of icy bodies beyond the orbit of Neptune at the edge of the solar system, Eris and Makemake are comparable in size to Pluto and its moon Charon.

CREDIT

Southwest Research Institute

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